Integrated OPC verification tool

ABSTRACT

An integrated verification and manufacturability tool provides more efficient verification of integrated device designs than verification using several different verification components. The integrated verification and manufacturability includes a hierarchical database to store shared design data accessed by multiple verification components (e.g., layout versus schematic, design rule check, optical process correction, phase shift mask assignment and OPC verification and machine language conversion). The hierarchical database includes representations of one or more additional, or intermediate layer structures that are created and used by the verification components for operations performed on the design being verified. Use of a single hierarchical database having shared data for access and use by multiple verification components streamlines the verification process, which provides an improved verification tool.

CROSS-REFERENCES TO RELATED APPLICATIONS

The present application is a continuation of Ser. No. 11/209,252, filed Aug. 22, 2005, which is a continuation-in-part of U.S. patent application Ser. No. 10/112,223, filed Mar. 27, 2002 (now U.S. Pat. No. 7,017,141 B2), which is a divisional of U.S. patent application Ser. No. 09/747,190, filed Dec. 22, 2000 (now U.S. Pat. No. 6,415,421), which is a continuation-in-part of U.S. patent application Ser. No. 09/593,923, filed Jun. 13, 2000 (now U.S. Pat. No. 6,425,113), the benefits of which are claimed under 35 U.S.C. §120 and which are herein incorporated by reference.

FIELD OF THE INVENTION

The invention relates to design tools for integrated device layouts. More particularly, the invention relates to an integrated tool for use in modifying and verifying integrated device layouts.

BACKGROUND OF THE INVENTION

Large scale integrated circuits or other integrated devices are designed through a complex sequence of transformations that convert an original performance specification into a specific circuit structure. Automated software tools are currently used for many of these design transformations. The description of the circuit at this stage is often called a “netlist”.

Automated tools exist to convert this netlist into a physical layout for the circuit. FIG. 1 illustrates one approach to conversion of the netlist to a physical layout. The layout defines the specific dimensions of the gates, isolation regions, interconnects, contacts, and other device elements that form the physical devices, and usually represents these shapes with polygons defining their boundaries.

The layout typically contains data layers that correspond to the actual layers to be fabricated in the circuit. The layout also contains cells, which define sets of particular devices within the circuit. Cells typically contain all the polygons on all the layers required for the fabrication of the devices it contains. Cells can be nested within other cells, often in very intricate arrangements. The structure of cells is often called a data hierarchy. Typical formats for the polygons of a physical layout are GDS II, CIF or OASIS.

Once the layout is created, the layout is verified to ensure that the transformation from netlist to layout has been properly executed and that the final layout created adheres to certain geometric design rules. These layout verification operations are often called LVS (layout versus schematic) and DRC (design rule check), respectively. To perform this verification step, several products have been created, including DRACULA™ from Cadence Design Systems of San Jose, Calif., HERCULES™ from Synopsis Corporation of Mountain View, Calif., and CALIBRE® from Mentor Graphics of Wilsonville, Oreg. When anomalies or errors are discovered by these checking tools, the designer must then repair the fault before the layout is sent to a mask shop for mask manufacturing and wafer fabrication.

An additional checking step can also be used for layout verification. FIG. 2 illustrates an enhanced approach to conversion of the netlist to a physical layout. This provides a simulation based software engine that predicts what manufacturing distortions will occur during lithographic patterning. If the magnitude of these errors is determined to be significant, corrections are made using some form of Optical and Process Correction (OPC). OPC can correct for image distortions, optical proximity effects, photoresist kinetic effects, etch loading distortions, and other various process effects. Phase-shifting features can also be added to the layout at this point to enhance contrast.

Examples of this kind of checking and correction can be found in “Automated Determination of CAD Layout Failures Through Focus: Experiment and Simulation,” by C. Spence et. al, in Optical/Laser Microlithography VII, Proc. SPIE 2197, p. 302 ff. (1994), and “OPTIMASK: An OPC Algorithm for Chrome and Phase-shift Mask Design” by E. Barouch et al. in Optical/Laser Microlithography VIII, Proc. SPIE 2440, p. 192 ff. (1995). The prior art techniques mentioned above comprise operating on the layout with a series of distinct software tools that execute all the required steps in sequence.

FIG. 3 is a conceptual illustration of an example of such a prior art process of integrated circuit (IC) design verification and correction. Each of the required process steps is executed by a stand-alone software tool. Original IC layout 300 describes the physical circuit layers from which masks and/or reticles are created to realize the circuit described by the design layout: the original IC layout 300 can be, for example, a GDS-II description of the circuit to be manufactured.

Data import process 310 converts original IC layout 300 to a format for storage in database 315. The data, as stored in verification database 315, is used by layout versus schematic (LVS) tool 320 and design rule checking (DRC) tool 325 to verify the design of original IC layout 300. Upon completion of LVS and DRC verification, the data stored in verification database 315 is exported by data export process 330.

The data is then imported by a data import process 335, which converts the exported data to a format used for a phase shift mask (PSM) database 340. PSM tool 345 operates on the data stored in PSM database 340 to perform phase shifting where appropriate. Examples of stand alone PSM assignment tools are SEED, discussed in the reference by Barouch, above, and the IN-Phase™ product available from Numerical Technologies of San Jose, Calif. The data describing the phase shifted layout(s) are exported from PSM database 340 by a data export process 350.

A data import process 355 imports the data generated by the PSM tool to an optical process correction (OPC) database 360. OPC database 360 is typically a flat database, meaning that all the polygons of a layer of the circuit are contained within a single cell, with no hierarchical structure. Data import process 355 typically converts data from a hierarchical representation to a flat representation. OPC tool 365 performs OPC operations on the data stored in OPC database 360. Examples of stand alone OPC tools are OPTIMASK, discussed in the reference by Barouch, above, and Proteus™ available from Synopsis Corporation. A data export process 370 exports the data stored in OPC database 360.

The data generated by the OPC tool is then typically imported into a simulation tool, to confirm that the OPC will have the desired corrective effect. This is sometimes called an optical and process rule check, or ORC. ORC checks can be run before OPC to determine if OPC is even necessary, at an intermediate point in an OPC run to determine if the results are good enough or after OPC has been completed. Once this check is complete, the data is exported for use in IC manufacturing process 395. As a final verification step, LVS tool 320 and/or DRC tool 325 can also be used on the output of OPC database 360. Performing another check with LVS tool 320 and/or DRC tool 325 requires another import and export by data import process 310 and data export process 330, respectively.

Several problems exist with respect to the process illustrated in FIG. 3. For example, the importation and exportation of data to and from each tool provides an opportunity for error in the form of loss, or inaccurate translation, of data. The importation and the exportation of large datasets, now common for VLSI ICs, is also time consuming, where a single import or export step can last several hours. The more complex an integrated circuit design, the more time consuming the importation and exportation steps become. It is therefore desirable to have a new verification tool in which all the required operations can be preformed, but where the risk of inaccurate translation is eliminated, and the many time consuming import and export steps are not required.

SUMMARY OF THE INVENTION

An integrated verification and manufacturability tool having a hierarchical database to represent at least a portion of an integrated device layout in a hierarchical or flat manner, which is used not only for standard DRC and LVS verifications, but is also capable of performing optical and process correction (OPC) and other data manipulation techniques, including phase-shifting mask (PSM) assignment and silicon simulation for optical and process rule checking (ORC) and OPC verification. In one embodiment an integrated software tool exports the verified data in the database in a machine language that can be read by a mask writer to produce one or more photolithographic masks.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

FIG. 1 is representation of standard IC layout design sequence used for verification.

FIG. 2 illustrates a modified flow, which accommodates additional process steps of OPC and PSM generation.

FIG. 3 is a conceptual illustration of a prior art implementation of integrated circuit design verification incorporating these additional steps.

FIG. 4 is a conceptual illustration of an integrated verification and manufacturability tool.

FIG. 4A shows an alternative embodiment of the invention wherein the integrated verification and manufacturability tool includes a component that exports verified data in a machine language that can be read by a mask writer.

FIGS. 4B and 4C illustrate another embodiment of the present invention including an OPC verification component that accesses a shared hierarchical database.

FIG. 4D illustrates a portion of an integrated circuit layout including a number of edge fragments and simulation sites.

FIGS. 4E and 4F illustrate a dense simulation sampling pattern over an integrated circuit layout design.

FIG. 5 illustrates operation of one embodiment of an integrated verification and manufacturability tool.

FIG. 6 illustrates one embodiment of a computer system suitable for use in practicing the invention.

FIG. 7 is a flow diagram of one embodiment of design verification with an integrated verification and manufacturability tool.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

An integrated verification and manufacturability tool is described. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the invention. It will be apparent, however, to one skilled in the art that the invention can be practiced without these specific details. In other instances, structures and devices are shown in block diagram form in order to avoid obscuring the invention.

Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.

Methods and apparatuses are described herein with respect to integrated circuit manufacturing; however, the techniques described can be applied to the manufacturing and/or design process of any integrated device. Integrated devices include integrated circuits, micromachines, thin film structures such as disk drive heads, gene chips, microelectromechanical systems (MEMS), or any other article of manufacture that is manufactured using lithography techniques.

An integrated verification and manufacturability tool provides more efficient verification of integrated device designs than verification using several different verification tools. The integrated verification and manufacturability tool includes a hierarchical database to store design data accessed by multiple verification tool components (e.g., layout versus schematic, design rule check, optical process correction, phase shift mask assignment). The hierarchical database includes representations of one or more additional or intermediate layer structures that are created and used by the verification tool components for operations performed on the design being verified. Designs can include only a single layer; however, the hierarchical database can include one or more intermediate layers for a single layer original design. Use of a single hierarchical database for multiple verification steps streamlines the verification process, which provides an improved verification tool.

FIG. 4 is a conceptual illustration of an integrated verification and manufacturability tool. The integrated verification and manufacturability tool of FIG. 4 includes a single hierarchical database that is used by each component within the tool. For purposes of description, the integrated verification and manufacturability tool includes a database and multiple components. The components perform the core functionality of the individual stand alone tools of FIG. 3; however, because they are included in an integrated verification and manufacturability tool, the individual components are not referred to as tools. Use of a single database for multiple components reduces the time and effort required for the verification process.

FIG. 4 illustrates an LVS component, a DRC component, an optical rule checking (ORC) component, a PSM component, an OPC component, and an “other” component 470 indicating that additional components can be added to the integrated verification and manufacturability. In alternate embodiments, fewer components can be used, for example, only a DRC and an OPC component might be used.

In one embodiment, the tool scans a listing of desired operations to be performed, sometimes called a “ruledeck,” to determine the required inputs and outputs. The tool then reads in the required input layers from the input database and creates empty output layers, to be filled during computation. In addition, several intermediate or “working” layers may be created to hold temporary computation results. In one embodiment, all inputs, outputs and intermediate results are geometry collections called “layers,” defined as a collection of geometry in one or more cells of the layout. This definition is the same as a definition of a layer in the well known GDS II database standard format for representing layouts. Layers also allow hierarchical data representation.

Once the hierarchical database is formed and the list of required layers compiled, computations are carried out to fill the desired output layers. After the verification process is complete, the information stored in hierarchical database 410 is exported by data export process 480. The exported data can be used by IC manufacturing process 395 to manufacture the IC design.

LVS component 440, DRC component 450, ORC component 460, PSM component 420, OPC component 430, and any other component(s), as indicated by “other” 470, operate on hierarchical data representing original IC layout 300 as stored in hierarchical database 410. In one embodiment, LVS component 440, DRC component 450, ORC component 460, PSM component 420, and OPC component 430 operate on a hierarchical representation of edges that describe original IC layout 300. The various components use the edge representations and the structures in the intermediate layers included in hierarchical database 410 to perform the respective operations.

Another embodiment of an integrated verification and manufacturability tool includes a component that can add arrays of regular features, such as small squares to the layout in order to help with the planarization, or physical flatness, of the fabricated silicon. These features are sometimes called “dummy fill” or “planarization fill.” By analyzing the density of the features in the layout, low-density areas are identified and filled in with new features.

FIG. 5 illustrates operation of one embodiment of an integrated verification and manufacturability tool. As described in greater detail below, the integrated verification and manufacturability tool can be executed by one or more computer systems.

In one embodiment, integrated verification and manufacturability tool 500 imports data from original database 520 into modified database 510. Original database 520 can store the design to be verified in a relatively standard format, for example, GDS-II, while modified database 510 can store the design in a modified standard format, or in an independent format. In one embodiment, importation includes executing hierarchical injection and/or bin injection. In an alternate embodiment, the integrated verification and manufacturability tool 500 receives the data in the modified/independent format.

In general, hierarchical injection is a technique in which recurring patterns of cell placements are recognized and replaced with new cells that contain the patterns. Hierarchical injection creates a more efficient representation of original database 520 by reducing the number of redundant patterns of cell placements, or contexts. In one embodiment, specially designed heuristics are used to recognize the patterns and to determine the correct representation by the new cells.

The heuristics include, for example, the injection of hierarchy into arrays and the selective flattening of densely overlapping structures. In many layouts, arrays of a cell are described inefficiently from a verification perspective. The hierarchical injection heuristics recognize arrays and redefine rows, columns or small sub-arrays as new cells.

This added hierarchy reduces the amount of geometry promoted during the computation phase by greatly reducing the number of redundant interactions between placements in the array. In particular types of circuits, for example FPGAs, two large cells or arrays of cells will overlap each other to a large extent. This configuration is called a “dense overlap.” Hierarchical injection recognizes such instances and first flattens selected cells that overlap, and then re-introduces new, less interaction-prone cell structures.

Bin injection is a process of dividing flat layout geometry into cells. Bin injection can also be applied to a random collection of cells, to reconfigure the cell structure more efficiently. In one embodiment, bin injection is accomplished by dividing a layout not by cell names, but by geometric grid. Bin injection is one technique for converting a flat layout into a hierarchical layout.

Various importation techniques are described in greater detail in U.S. patent application Ser. No. 09/234,030 filed Jan. 19, 1999 (now U.S. Pat. No. 6,381,731), entitled “PLACEMENT BASED DESIGN CELLS INJECTION INTO AN INTEGRATED CIRCUIT DESIGN,” by Laurence W. Grodd, which is incorporated by reference herein.

Once modified database 510 is generated by hierarchical injection and/or bin injection, each component (e.g., LVS, DRC, PSM, OPC, ORC) operates on groups of geometric figures that represent portions of the layout of the integrated device design. These groups are generally referred to as an “edge collection.” An edge collection contains edges from a design that may be organized into polygons, depending on the nature of the operations. Typical edge collections may contain only the edges of a single cell; others may contain the edges of a cell and nearby elements, while others might contain all edges within an arbitrary boundary. Edges may be retrieved from the edge collection either as whole polygons, if the data they represent consists of polygons, or as free edges. Once retrieved and manipulated, new edges representing the output of the operation are stored in a layer from which the edges are retrieved and/or a previously unused intermediate layer in modified database 510.

Selective promotion is a technique in which certain geometries in cells that have an effect on nearby cells are “promoted” to another level of the hierarchy. This promotion prevents the geometry in a cell from having conflicting behavior depending on the placement of the cell. For example, for a cell that has geometry very close to its own border, one placement of this cell may be isolated, but another placement may be close to another cell. In this case, the computed result for the geometry near the border may be different in each placement due to interaction with the nearby cell. Further detail of selective promotion can be found in Mentor Graphic's U.S. Pat. No. 6,668,367, which is also herein incorporated by reference.

To resolve this conflict, the conflicting geometry close to the border is “promoted,” or flattened, to the next level of the hierarchy. This creates two versions of the geometry, one for each placement of the cell, each of which will produce different computational results. By reducing the number of unique interactions and conflicting geometries, the amount of promoted geometry is minimized, resulting in less computation and smaller file size. Promotion can be accomplished recursively.

Manipulation of edge collections, as well as the use of selective promotion facilitates sharing of data between multiple verification tool components without importation and exportation of data between databases. Previous verification tools typically represent IC designs in formats that are optimized for the specific tool without regard for sharing the design database. Sharing of data was accomplished through an importation/exportation process.

The hierarchical representation provided by modified database 510 provides several performance advantages. For example, previous verification tools typically used a cell cloning scheme to eliminate redundant contexts. However, some designs resulted in a very large number of clones which slowed the verification process. Selective promotion and hierarchical injection reduces, or even eliminates, redundant contexts in a more efficient manner, which allows the verification process to be completed more quickly than using a cloning-based technique.

Additionally, cloning techniques are based on the assumption that all inter-cell interactions are local. That is, interaction distances are bounded. However, for phase-shift mask (or reticle) assignment techniques, interaction distances are potentially unbounded. This requires a potentially unbounded number of cell clones, which would make hierarchical phase assignment impractical.

In one embodiment, the integrated verification and manufacturability tool includes an LVS component 440 and a DRC component 450 that perform both LVS verification operations and DRC verification operations on the edge collection stored in modified database 510. In an alternate embodiment, LVS verification operations and DRC verification operations are performed by separate components.

The LVS verification operations analyze the edge collection to determine whether the layout accurately corresponds to the schematic design. In one embodiment, the edge collection is compared to a netlist corresponding to the design to determine whether the layout accurately represents the netlist representation. Errors identified by the LVS component can be flagged, identified and possibly corrected. In one embodiment, data generated by the LVS component and/or the corrected layout are stored in one or more intermediate layers in modified database 510.

The DRC verification operations analyze the edge collection to determine whether any design rule violations exist. Design rules can include, for example, minimum line spacings, minimum line widths, minimum gate widths, or other geometric layout parameters. The design rules are based on, for example, the manufacturing process to be used to manufacture the resulting design layout. As with the LVS component, errors identified by the DRC component can be flagged, identified and possibly corrected. In one embodiment, data generated by the DRC component and/or the corrected layout are stored in one or more intermediate layers in modified database 510.

In one embodiment, ORC component 460 analyzes the edge collection by simulating the performance expected on the wafer, and determines whether the wafer structures will violate a set of fabrication tolerances. ORC component 460 can also operate on the edge collection that represents the original layout, for example, prior to LVS and DRC being performed on the layout. This operation can include creating new data layers in the hierarchical database 410 as a representation of the wafer as it will be printed, sometimes called a “printImage” calculation, which can subsequently be checked using the DRC, LVS or other components. As with the LVS and DRC components, errors identified by the ORC component can be flagged and identified and possibly corrected.

In one embodiment, PSM component 420 operates on an edge collection as modified by ORC component 460; however PSM component 420 can operate on other edge collections also. PSM component 420 creates phase shifting assignments for reticles of the design stored in modified database 510. Phase shifting assignments can be made, for example, to enable extremely small gate widths and/or line widths. The resulting layers and/or reticle layers are stored in intermediate layers in modified database 510.

In one embodiment, OPC component 430 operates on the edge collection as modified by PSM component 420 and stored in one or more intermediate layers in modified database 510. OPC component 430 can also operate on the edge collection that represents the original layout, for example, if PSM is not performed on the layout.

Two general categories of OPC are currently in use: rule-based OPC and model based OPC; one or both of which can be applied. In rule-based OPC, a reticle layout is modified according to a set of fixed rules for geometric manipulation. In model-based OPC, an IC structure to be formed is modeled and a threshold that represents the boundary of the structure on the wafer can be determined from simulated result generated based on the model used.

Certain aspects of model-based OPC are described in greater detail in the following publications: Cobb et al., “Mathematical and CAD Framework for Proximity Correction,” Optical Microlithography IX, Proc. SPIE 2726, pp. 208-222 (1996); Cobb et al., “Experimental Results in Optical Proximity Correction with Variable Threshold Resist Model,” Optical Microlithography X, SPIE 3051, pp. 458-468 (1998); and Nicholas B. Cobb, “Fast Optical and Process Proximity Correction Algorithms for Integrated Circuit Manufacturing,” Ph.D. dissertation, Univ. Cal. Berkeley (1998).

OPC component 460 modifies the placement of one or more edges to provide improved optical performance of one or more reticles. One example of rule-based OPC that can be applied to a layout is the addition of assist features, for example, sub-resolution bars along an interconnection line, hammer head shapes at line ends, or serifs at a line corner. Other assist features can also be provided.

OPC component 460 can also modify placement of one or more edges based on models that predict the structures that will be produced using specific reticle layouts. The reticle layouts can be modified based on the results of the prediction to compensate for deficiencies that are identified by the modeling results. In one embodiment, the results Generated by OPC component 460 are stored in one or more intermediate layers in modified database 510.

In yet another embodiment of the invention, the other component 472 of the integrated verification and manufacturability tool shown in FIG. 4A converts the optimized, shared data within the database into a format that can be supplied directly to a mask creating tool. Most mask creating tools use layout data in machine specific formats, such as MEBES for E-Beam and laser rasterizing writing tools, such as those from ETEC systems (an applied Materials Company), Hitachi format for Hitachi vector scan E-beam mask writers, .MIC format for hierarchical processing in mask writers from Micronic Corporation. Preparation of data for these mask writers typically involves importing layout data (typically GDS II) into a stand-alone translation tool to convert the standard format to the machine specific format.

Mask writing tools include raster scanning mask writing tools, vector scan mask writing tools, tools that utilize a parallel array of mask writing elements including arrays of microscopic mirrors, independently modulated laser beams, scanning probe microscope elements or other mechanisms that create photolithographic masks or reticles.

The component 472 therefore executes computer code that determines the form in which the data is to be exported, either by prompting a user for such a selection or based on a default etc. Next, the component converts a desired portion, such as an individual data layer, of the shared data within the database into the selected mask writing language. Data may also be called and translated as subsets of the data layer, to be processed independently or in parallel, to increase translation precision or speed.

In the presently preferred embodiment of the invention in which the database is hierarchical, the conversion of the database to the desired mask writing language includes the steps of reading a portion of the data layer into temporary memory, processing the portion according to the machine specific translation specifications, and writing the translated portion into an output file. This is repeated until the entire layer has been converted, portion by portion. Although it will be appreciated that the job can be more manageable when divided by portions or other subsets of the data layer, another embodiment that may have advantages in some circumstances comprises moving the entire data layer to be converted into a flattened data layer, then converting the entire flattened layer into the specified machine language.

As will be appreciated, by including a component 472 that can export the verified and optimized design data directly in the mask writing machine language, there is less chance of error due to compatibility problems between software systems. In addition, the time required to process the layout data and produce a mask is also reduced.

For the purpose of the present specification and claims, the term “mask” is intended to cover both conventional photolithographic contact printing masks as well as reticles or other devices on which patterns are formed that determine whether illumination light is allowed to reach a wafer.

In another embodiment of the invention, the “other” integrated verification component 470 shown in FIG. 4 that interacts with a common hierarchical database 410 is an OPC verification component. In conventional processing, a layout or portion thereof to be corrected was simulated and OPC corrections were made in order to improve the fidelity with which an integrated circuit mask can print patterns on a wafer. Once the corrections were made, the corrected data was exported to an OPC verification tool that uses its own database and simulation model in order to determine whether the mask layout design was correctly modified. In the manner similar to that shown in FIG. 3, such a tool requires a number of data export/data import steps in order to supply the corrected data to the OPC verification tool. The tool then performed its analysis and returned the results back to the user to make any further changes before a mask or reticle could be manufactured.

As indicated above, such data export/import is time consuming and is a source of potential errors. To overcome these and other limitations, one embodiment of the present invention incorporates an OPC verification component an integrated verification tool having access to a shared hierarchical database 410. As shown in FIG. 4B, a set of integrated verification components includes two or more of an optical rule checker 460, OPC component 430, and an OPC verification component 482 and the additional components discussed above. Each of the components 430, 460, and 482 access a simulation engine 484 in order to estimate how a feature on a mask or reticle will print on a wafer. The OPC verification component 482 accesses a common hierarchical database 410 in order to retrieve the integrated circuit layout design or portion thereof in order to confirm that the OPC corrections made by the OPC component 430 will print as desired on a wafer. By including the OPC verification component 482 in the suite of integrated component, it is not necessary to export the data to a separate tool, thereby saving time associated with such an export/import process and the possibility that an error may occur during the exporting process. The OPC verification component preferably operates on the data as it is stored in the hierarchical database such as in a GDS-II or OASIS format.

In the embodiment shown in FIG. 4B, the OPC verification component 482 accesses the same simulation engine 484 used by the ORC component 460 and the OPC component 430. However, in some instances it may be desirable for the OPC verification component 482 to use a different simulation engine.

FIG. 4C illustrates an embodiment of the present invention whereby the OPC verification component 482 accesses a different simulation engine 486 in order to estimate how a feature on a mask or reticle will print on a wafer. The simulation engine 486 may be more accurate than the simulation engine 484. Because the OPC verification component typically analyzes the data in a single pass, versus an iterative approach used by the OPC component 430, a more accurate model can be used without incurring significant additional calculation time.

FIG. 4D illustrates a conventional way in which an OPC verification component determines whether the corrections made by the OPC component are correct. In general, an OPC verification component analyzes a layout by determining where each of the edges of the mask features will print on a wafer. A simulation of each edge is made at a simulation site. In the example shown in FIG. 4D, the simulation sites 486 are typically positioned midway between fragmentation endpoints. However, there may be more optimal methods of selecting simulation sites such as those described in U.S. patent application Ser. No. 10/698,596 filed Oct. 31, 2003 and Ser. No. 11/067,504 filed Feb. 25, 2005 both of which are assigned to Mentor Graphics Corporation, the assignee of the present invention and herein incorporated by reference.

In some instances, using simulation sites that are the same as those used by the OPC component to determine the OPC corrections can lead to errors. For example, the OPC component may determine that assist features are required to be placed into the layout design. If the OPC verification component only analyzes the layout at the same simulation sites used by the OPC component, without placing simulation sites on the assist features, then it is not possible to confirm that the assist features will not print on a wafer. Furthermore, the reuse of the same simulation sites can introduce other errors that will otherwise not be detected by the OPC verification component.

To overcome this difficulty, one embodiment of the present invention uses a different site selection system for the OPC verification component than is used by the OPC component. As shown in FIG. 4E, the OPC verification component can use a uniform grid of simulation sites 490 to estimate the aerial image intensity in a region. A pattern of equally placed simulation sites, where the spacing is small compared to the layout feature size, is often referred to as “dense” simulation. The pattern of simulation sites 490 may be uniform across the layout as shown in FIG. 4E. Alternatively, the patterns of simulation sites may vary. For example, FIG. 4F shows a pattern of simulation sites 492 having a first density and a pattern of simulation sites 494 having a second, increased density. In general it is desirable to increase the density of simulation sites in areas that are critical to circuit operation and to decrease the density in non-critical areas to reduce run time. The particular density is limited by the optical parameters of the system being simulated: wavelength λ, numerical aperture NA, and the illumination conditions σ. These parameters define a spatial frequency cutoff, beyond which no image modulation will occur. Therefore, it is often common to set the period of sampling points to occur at the Nyquist frequency for the optical system, or at twice the Nyquist frequency when squaring the optical field into an intensity, in order to provide a compromise between accuracy and oversampling. Beyond this sampling frequency, sampling at finer grids yields redundancy, not more information.

By using a different arrangement of simulation sites than that used by the OPC component, it is possible that the OPC verification component may detect errors not otherwise corrected if the same simulation sites are used as were used by the OPC component. Furthermore, as indicated above, the calculations performed with the different sample site pattern such as that shown in FIGS. 4E and 4F, may use the same simulation engine as the OPC component or may use a different simulation engine.

In the example shown above, the OPC component 430 uses a “sparse” simulation by placing simulation sites on the edge fragments themselves. However it will be appreciated that the OPC component can also use a dense simulation. In cases where a simulation site does not coincide with an edge fragment exactly, it is often necessary to map a particular simulation site to an edge fragment. In order to avoid potential problems that occur when the OPC component and OPC verification component use the same simulation site layout, the layout of dense simulation sites used by both components should differ.

FIG. 6 is a block diagram of one embodiment of a computer system. The computer system illustrated in FIG. 6 is intended to represent a range of computer systems. Alternative computer systems can include more, fewer and/or different components.

Computer system 600 includes a bus 601 or other communication device to communicate information, and a processor 602 coupled to the bus 601 to process information. While the computer system 600 is illustrated with a single processor, the computer system 600 can include multiple processors and/or co-processors. In a multiprocessor embodiment, operations performed by the various verification and manufacturability components are divided by cells, bins or other techniques for dividing work between processors. For example, a single cell is operated upon by a processor while another cell is operated upon by a different processor. When the cell operations are complete, the processor can perform verification operations on another cell.

Computer system 600 further includes random access memory (RAM) or another dynamic storage device 604 (referred to as main memory), coupled to a bus 601 to store information and instructions to be executed by a processor 602. Main memory 604 also can be used to store temporary variables or other intermediate information during execution of instructions by a processor 602.

Computer system 600 also includes read only memory (ROM) and/or other static storage device 606 coupled to a bus 601 to store static information and instructions for a processor 602. Data storage device 607 is coupled to a bus 601 to store information and instructions. Data storage device 607 such as a magnetic disk or optical disc and corresponding drive can be coupled to a computer system 600.

Computer system 600 can also be coupled via a bus 601 to a display device 621, such as a cathode ray tube (CRT) or liquid crystal display (LCD), to display information to a computer user. Alphanumeric input device 622, including alphanumeric and other keys, is typically coupled to a bus 601 to communicate information and command selections to a processor 602. Another type of user input device is a cursor control 623, such as a mouse, a trackball, or cursor direction keys to communicate direction information and command selections to a processor 602 and to control cursor movement on a display 621.

Computer system 600 further includes a network interface 630 to provide access to a network, such as a local area network. According to one embodiment, an integrated verification and manufacturability tool is provided by one or more computer systems, such as a computer system 600, or other electronic device in response to one or more processors, such as a processor 602, executing sequences of instructions contained in memory, such as a main memory 604.

Instructions are provided to memory from a storage device, such as magnetic disk, a read only memory (ROM) integrated circuit, CD-ROM or DVD, via a remote connection (e.g., over a network via network interface 630) that is either wired or wireless, etc. In alternative embodiments, hard-wired circuitry can be used in place of, or in combination with, software instructions to implement the present invention. Thus, the present invention is not limited to any specific combination of hardware circuitry and software instructions.

A machine-readable medium includes any mechanism that provides (i.e., stores and/or transmits) information in a form readable by a machine (e.g., a computer). For example, a machine-readable medium includes read only memory (ROM), random access memory (RAM), magnetic disk storage media, optical storage media, flash memory devices, electrical, optical, acoustical or other form of propagated signals (e.g., carrier waves, infrared signals, digital signals, etc.).

FIG. 7 is a flow diagram of one embodiment of design verification with an integrated verification and manufacturability tool. FIG. 7 illustrates a specific sequence through a specific set of verification procedures. The specific verification procedures and the sequence in which verification is performed can be modified based on, for example, the type of design being verified.

Data describing the integrated device design is imported at 710. In one embodiment, the data is imported from a GDS-II file; however, other formats can also be used. In general, conversion of data from one format to another is known in the art. As mentioned above, during importation, intermediate layers are added to the imported data to be stored in a hierarchical database.

In one embodiment, the number of intermediate layers added is determined based on the verification procedures to be performed, and possibly on the sequence in which the verification procedures are performed. One or more intermediate layers are added for each of the verification procedures to be performed. In one embodiment, a job description is analyzed in association with importation of an integrated device design. The job description indicates the verification procedures to be performed and the portions of the design that are to be verified.

Layout versus schematic (LVS) verification is performed at 720. In general, LVS verification compares the original design layout to a netlist that described the interconnections of components within the design. The intermediate layer(s) associated with LVS verification stores the results of the LVS verification. The intermediate layer(s) can store, for example, a description of errors found during LVS verification, or a modified design based on the results of the LVS verification process.

Design rule checking (DRC) is performed at 720. DRC searches the design for violations of a predetermined set of conditions (e.g., minimum line widths, minimum separations) and returns a result indicating whether design rule violations were found. The intermediate layer(s) associated with DRC can store, for example, a list of design rule errors found, or a modified design that satisfies the design rules. Optical rule checking (ORC) is performed at 740. In one embodiment, the ORC is performed on one or more simulated integrated device layers.

In one embodiment, ORC includes “flagging” edges in a layout that are predicted to result in silicon printability errors. In another embodiment, simulated silicon shapes are generated from the layout, then DRC is performed on the simulated silicon shapes. This can be thought of as “silicon DRC” or another application ORC.

Phase shift mask assignments are made at 750 and an optical process correction is performed at 760. OPC verification is then performed at 765. Data may be exported at 770 in the format in which it is stored in the database. Alternatively, if the integrated verification and manufacturability tool includes an integrated component that converts the shared data into a mask writing machine language, the data may be exported in a form that can be read by a mask writing tool directly.

In the foregoing specification, the invention has been described with reference to specific embodiments thereof. It will, however, be evident that various modifications and changes can be made thereto without departing from the broader spirit and scope of the invention. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.

While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention. 

1. An integrated verification and manufacturability tool comprising: a hierarchical database to represent at least a portion of an integrated device layout in a hierarchical manner; an optical and process correction (OPC) component that operates on the integrated device layout by accessing said hierarchical database, and determining corrections for one or more edge fragments in the integrated device layout and storing the corrections in the hierarchical database; and an optical and process correction (OPC) verification component that operates on the integrated device layout by accessing the OPC corrections stored in the hierarchical database and analyzing them with a simulation engine to ensure that the edge fragments of the integrated device design will print as desired.
 2. The integrated verification and manufacturability tool of claim 1, wherein the integrated verification and manufacturability tool further comprises a layout versus schematic (LVS) component.
 3. The integrated verification and manufacturability tool of claim 1, wherein the integrated verification and manufacturability tool further comprises a design rule checking (DRC) component.
 4. The integrated verification and manufacturability tool of claim 1, wherein the integrated verification and manufacturability tool further comprises a phase shift mask (PSM) component.
 5. The integrated verification and manufacturability tool of claim 1, wherein the integrated verification and manufacturability tool further comprises an optical rule checking (ORC) component.
 6. The integrated verification and manufacturability tool of claim 1, wherein the OPC component and the OPC verification component analyze the integrated device layout at a number of simulation sites and wherein at least some of the simulation sites used by the OPC verification component are different from the simulation sites used by the OPC component.
 7. The integrated verification and manufacturability tool of claim 6, wherein the OPC verification component analyzes the integrated device layout with a dense grid of simulation sites.
 8. The integrated verification and manufacturability tool of claim 7, wherein the dense grid of simulation sites is uniform.
 9. The integrated verification and manufacturability tool of claim 7, wherein the dense grid of simulation sites is variable. 